The post-stroke young adult brain has limited capacity to re-express the gene expression patterns seen during early postnatal brain development

IF 5.8 2区 医学 Q1 CLINICAL NEUROLOGY
Brain Pathology Pub Date : 2024-01-10 DOI:10.1111/bpa.13232
Mihai Ruscu, Bogdan Capitanescu, Paul Rupek, Thomas Dandekar, Eugen Radu, Dirk M. Hermann, Aurel Popa-Wagner
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Abstract

The developmental origins of the brain's response to injury can play an important role in recovery after a brain lesion. In this study, we investigated whether the ischemic young adult brain can re-express brain plasticity genes that were active during early postnatal development. Differentially expressed genes in the cortex of juvenile post-natal day 3 and the peri-infarcted cortical areas of young, 3-month-old post-stroke rats were identified using fixed-effects modeling within an empirical Bayes framework through condition-specific comparison. To further analyze potential biological processes, upregulated and downregulated genes were assessed for enrichment using GSEA software. The genes showing the highest expression changes were subsequently verified through RT-PCR. Our findings indicate that the adult brain partially recapitulates the gene expression profile observed in the juvenile brain but fails to upregulate many genes and pathways necessary for brain plasticity. Of the upregulated genes in post-stroke brains, specific roles have not been assigned to Apobec1, Cenpf, Ect2, Folr2, Glipr1, Myo1f, and Pttg1. New genes that failed to upregulate in the adult post-stroke brain include Bex4, Cd24, Klhl1/Mrp2, Trim67, and St8sia2. Among the upregulated pathways, the largest change was observed in the KEGG pathway “One carbon pool of folate,” which is necessary for cellular proliferation, followed by the KEGG pathway “Antifolate resistance,” whose genes mainly encode the family of ABC transporters responsible for the efflux of drugs that have entered the brain. We also noted three less-described downregulated KEGG pathways in experimental models: glycolipid biosynthesis, oxytocin, and cortisol pathways, which could be relevant as therapeutic targets. The limited brain plasticity of the adult brain is illustrated through molecular and histological analysis of the axonal growth factor, KIF4. Collectively, these results strongly suggest that further research is needed to decipher the complex genetic mechanisms that prevent the re-expression of brain plasticity-associated genes in the adult brain.

Abstract Image

Abstract Image

中风后的年轻成人大脑重新表达出生后早期大脑发育过程中出现的基因表达模式的能力有限。
大脑对损伤反应的发育起源对脑损伤后的恢复起着重要作用。在这项研究中,我们探讨了缺血的年轻成人大脑是否能重新表达出生后早期发育过程中活跃的大脑可塑性基因。在经验贝叶斯框架内,通过条件特异性比较,使用固定效应模型确定了出生后第 3 天幼年大鼠皮层和中风后 3 个月幼年大鼠梗死周围皮层中的差异表达基因。为了进一步分析潜在的生物过程,使用 GSEA 软件对上调和下调基因进行了富集评估。随后通过 RT-PCR 验证了表达变化最大的基因。我们的研究结果表明,成人大脑部分再现了在青少年大脑中观察到的基因表达谱,但未能上调大脑可塑性所需的许多基因和通路。在中风后大脑中上调的基因中,Apobec1、Cenpf、Ect2、Folr2、Glipr1、Myo1f 和 Pttg1 还没有被赋予特定的作用。在中风后成人大脑中未能上调的新基因包括Bex4、Cd24、Klhl1/Mrp2、Trim67和St8sia2。在上调的通路中,变化最大的是 KEGG 通路 "叶酸一碳池",它是细胞增殖所必需的,其次是 KEGG 通路 "抗叶酸",其基因主要编码 ABC 转运体家族,负责将进入大脑的药物外流。我们还注意到,在实验模型中,有三个较少被描述的 KEGG 通路被下调:糖脂生物合成、催产素和皮质醇通路,它们可能是相关的治疗靶点。通过对轴突生长因子 KIF4 的分子和组织学分析,说明了成人大脑的可塑性有限。总之,这些结果有力地表明,需要进一步的研究来破译阻碍成人大脑可塑性相关基因重新表达的复杂遗传机制。
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来源期刊
Brain Pathology
Brain Pathology 医学-病理学
CiteScore
13.20
自引率
3.10%
发文量
90
审稿时长
6-12 weeks
期刊介绍: Brain Pathology is the journal of choice for biomedical scientists investigating diseases of the nervous system. The official journal of the International Society of Neuropathology, Brain Pathology is a peer-reviewed quarterly publication that includes original research, review articles and symposia focuses on the pathogenesis of neurological disease.
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